FR2962338A1 - DRY POWDER INHALER. - Google Patents

Abstract

A dry powder inhaler (100) having a body (110) containing a dispersion chamber (111), a hood (130) pivotally mounted on said body between a closed position and an open position, said hood having a dispensing orifice ( 131) through which the user inhales, the inhaler further comprising a loading opening (121) receiving a capsule (10) containing a dose of dry powder to be inhaled, the inhaler having a sliding member (140) meshed with said hood (130), moving said hood from its open position to its closed position moving said laterally translatable sliding member to open the capsule disposed in said loading opening (121).

Description

The present invention relates to a dry powder inhaler. Inhalers are well known in the state of the art. There are different kinds. A first type of inhaler contains a reservoir receiving a multitude of doses of powder, the inhaler being provided with dosing means allowing each actuation to separate a dose of this powder from the reservoir to bring it into an expulsion conduit to to be distributed to the user. Another type of inhaler consists in arranging the doses of powder in pre-dosed individual reservoirs and then opening one of these reservoirs each time the inhaler is actuated. This implementation ensures a better seal of the powder, since each dose is open at the time of its expulsion. To make these individual tanks, various variants have already been proposed, such as an elongated blister strip or blisters arranged on a rotating circular disk. All types of inhalers described above and existing have advantages and disadvantages related to their structure and operation. Thus, with some inhalers, there is the problem of accuracy and reproducibility of the dosage at each actuation. Also, the effectiveness of the delivery, that is, the portion of the dose that actually enters the user's lungs to have a beneficial therapeutic effect, is also a problem with some number of inhalers. Regarding the opening of the individual tanks, it has been proposed to peel or peel off the closure layer. This has the disadvantage of difficult control of the forces to be applied to ensure full opening without the risk of opening the next tank, particularly if the opening means is to be actuated by inhalation. Another problem that arises with inhalers provided with blister band is related to the displacement of the band, and the storage of the used part of the band. Thus, depending on the length of the strip and / or the thickness of the blisters, a large space may be necessary and any blocking of the blister strip may prevent the proper operation of the inhaler. Moreover, when the advancing device of the band pulls at the same time on the front end of the band to avoid a bad winding, it can be a problem as the actuations take place, in particular because of the diameter of the band. worn band wound up gradually. Multi-dose inhalers and inhaler containing a band of blisters are therefore generally complex devices, consisting of a large number of parts, and therefore expensive to manufacture and assemble. To achieve less complex and therefore less expensive devices, it has been proposed inhalers with individual reservoirs, such as capsules, to be loaded into the inhaler just before use thereof. The advantage of these devices is that it is not necessary to store all the doses inside the device, so that it can be reduced in size. By cons, the use is more complex, since the user is obliged to load a capsule in the inhaler before each use. In addition, other disadvantages specific to these capsule inhalers have appeared. Thus, these devices 15 are generally made of two parts, one being provided with the mouthpiece. When handling these devices, to open the capsule and release the powder, or to empty the empty capsule after inhalation, the fingers of the user generally come into contact with the mouthpiece, which may present risks of contamination . Similarly, to evacuate the empty capsule, the device must generally be disassembled, which exposes the interior of the device to any external pollution, may subsequently be transmitted to the user during a future inhalation. The present invention aims to provide a dry powder inhaler, which does not reproduce the aforementioned drawbacks. In particular, the present invention aims to provide such an inhaler that is simple and inexpensive to manufacture and assemble, reliable in use, and limiting as much as possible the risk of contamination and / or pollution. The present invention therefore relates to a dry powder inhaler, comprising a body containing a dispersion chamber, a cap pivotally mounted on said body between a closed position and an open position, said cap comprising a dispensing orifice through which user inhales, the inhaler further comprising a loading opening receiving a capsule containing a dose of dry powder to inhale, the inhaler having a sliding member meshed with said cover, moving said cover from its open position to its closed position moving said sliding member laterally in translation to open the capsule disposed in said loading opening. Advantageously, said capsule comprises an upper part and a lower part separable from said upper part, said sliding member cooperating with said lower part to separate it from said upper part when said cover returns to its closed position. Advantageously, said sliding member comprises at least one toothing cooperating with at least one toothed element integral in rotation with said cover. Advantageously, said sliding member is disposed below said loading opening in the right position of the inhaler, said sliding member having a first opening disposed facing said loading opening when the hood is in the open position, and a second opening arranged facing said loading opening when the hood is in the closed position. Advantageously, said lower part of the capsule passes through said first opening of said sliding member when the capsule is inserted into said loading opening. Advantageously, a plate portion is fixed on said body, said plate portion having said loading opening and guide means for guiding the translational movement of said sliding member. Advantageously, said guide means comprise rails cooperating with projections of said sliding member. These and other features and advantages of the present invention will appear more clearly in the following detailed description, with reference to the accompanying drawings, given by way of non-limiting examples, in which FIG. 1 is an exploded diagrammatic view. in perspective of a dispensing device according to an advantageous embodiment of the invention, - Figure 2 is a schematic cross-sectional view of the device of Figure 1, in the closed position before the first use, - Figure 3 is a view similar to that of Figure 2, in the open position, with a capsule loaded in the loading opening, - Figures 4 and 5 are views similar to that of Figure 2, during closure of the hood and FIG. 6 is a view similar to that of FIG. 2, in the closed position, before inhalation, FIG. 7 is a view similar to that of FIG. 6, in the closed position. e, during inhalation, - Figure 8 is a view similar to that of Figure 3, in the open position, - Figures 9 and 10 are schematic perspective views of the device of Figure 1, respectively in the closed position and Figs. 11 and 12 are schematic perspective cut-out views, respectively in closed and open position. The figures describe an advantageous embodiment of the invention. In this embodiment, the inhaler 100 includes a hollow body 110 and having an upper opening and a lower opening. The upper opening is at least partially closed by a plate portion 120 fixed to said body and the lower opening is closed by a closure element, such as a hatch 150, pivotally mounted on said body 110. plate 120 is interposed a sliding member 140 provided with a toothing. Advantageously, the plate portion 120 comprises guide means, such as rails 129, cooperating with projections 149 of the sliding member 140, for guiding the displacement i0 in translation of said sliding member. A pivoting cover 130 is assembled above said plate portion 120. This cover 130 includes the dispensing orifice 131, preferably formed at a mouthpiece around which the user will place his mouth to inhale. Thus, as can be seen in particular in FIG. 1, the device according to this embodiment consists of five main parts, namely the body 110, the plate portion 120, the sliding member 140, the cover 130 and the hatch 150. All of these elements are connected to one another by means of an axis 160 passing through a lateral opening 115 provided in the body 110, through appropriate lateral openings 135 of the cover 130 and through a hollow cylinder 155 formed in a portion of the hatch 150. At least one toothed element 161, 162 is mounted on said axis 160 to cooperate with at least one toothing 145 provided on the sliding member 140. In the example shown, there are two toothed elements 161 and 162 mounted on the axis 160, and therefore the sliding member 140 also has two sets of teeth 145 and 146, the operation of which will be described hereinafter. A suitable fastener 163 may be provided for releasably fixing said axis 160 to said body 110 by assembling the different constituent parts together. As can be seen in FIG. 1, the axis 160 preferably has a particular section, for example substantially square, and the toothed elements also comprise a similar section so that they are integral in rotation with the axis 160. the cover 130 also has openings 135 of similar shape so that the cover, the toothed elements and said axis 160 are integral in rotation. The plate portion 120 has a loading opening 121, advantageously provided with at least one, preferably three positioning ribs 125, advantageously evenly distributed around said loading opening 121. These ribs make it possible to position and maintain squeezing a capsule 10 in the desired position. In particular, the capsules 30 comprise an upper part 11 and a lower part 12 separable from said upper part, said ribs 125 serving to maintain said upper part 11 before and during the separation of said lower part 12. Moreover, this part of Plate 120 also advantageously comprises a reservoir zone 122 formed by an area provided with a plurality of holes 123 for disposing one or more reserve capsules. This allows the user to always have several capsules available, for example when traveling. In this case, after each use of the device, it only has to use in this capsule container to load the next capsule in the loading opening 121. Of course, such a capsule reservoir is not essential to the operation of the device. Figures 2 to 8 illustrate a cycle of operation of the device according to this embodiment. With reference to FIG. 2, which shows the device in the closed position before the first use, it can be seen that the body 110 defines inside a dispersion chamber 111 which will be intended to receive the powder after opening the capsule 10. FIG. 3 shows the device after opening the cover 130. It can be seen that the opening of the cover 130 causes the rotation of the axis 160 due to the cooperation of the approximately square shape of this axis 160 with the correspondingly shaped orifices 135 of said 130. This rotation of the axis 160 thus also causes a rotation of the toothed elements 161 and 162 which rotate with said axis 160. A rotation of these toothed elements 161, 162 causes a lateral translation of the sliding member 140. Indeed, as shown in particular in Figure 2, the toothing 165 of the toothed element 161 is engaged in the toothing 145 of the sliding member 140. Thus, between Figures 2 and 3, it can be seen that the rota Toothing 165 of the toothed element will slide the slide member 140 to the right in the figures. Of course, the same happens on the other side of the device with the second toothed element 162, not visible in the sectional figures. Of course, a single toothed element may be sufficient to cause the displacement of said sliding member. When opening the cover 130, the flap 150 does not rotate with the axis 160. On the other hand, at the end of opening of the cover 130, it cooperates with said flap 150, and in particular with a curved portion 151 connecting the hollow cylinder 155, which is mounted on the axis 160, to the portion of the hatch which closes the bottom of the body 110 in the closed position of the hatch. This cooperation between the cover 130 and the hatch 150 tilts the hatch about said axis 160 to the open position shown in Figure 3. Thus, in this fully open position of the cover 130, the hatch 150 is open and the inside of the dispersion chamber 111 may be discharged out of the device. FIG. 3 also shows a capsule 10 placed inside the loading aperture 121. It can be seen that the upper part 11 of the capsule is tightly held in the ribs 125 provided in said loading aperture 121 Furthermore, the lower part 12 of the capsule passes through a first opening 141 made in said sliding member 140 and which, in the open position of the cover 130, faces the said loading opening 121. FIGS. 6 illustrate the closing phase of the cover 130 after the capsule 10 has been loaded. Thus, as can be seen in FIG. 4, when the user closes the cover 130, the hatch 150 will also close and the sliding member 140 will be closed. brought back to the left in the figures by the cooperation between the toothed elements 161 and 162 and the teeth of said sliding member 140. Now, the lower part 12 of the capsule 10 passing through first opening 141 of said sliding member 140, a lateral displacement of this sliding member will break the lower portion 12 of the capsule 10 as shown in Figure 4. The upper portion 11 of the capsule 10 is of course maintained tightly in the loading opening 121, in particular by the ribs 125. On the other hand, the lower portion 12 will fall into the dispersion chamber 111, since the first orifice 141 of said sliding member 140 has a larger diameter than the outer diameter of said lower portion 12 of the capsule. Thus, not only will the powder be emptied into the dispersion chamber 111, but the lower portion 12 containing said powder will fall on the bottom of said dispersion chamber 111 to allow emptying thereof. In the position of Figure 5, we see that the hood 130 just before its closed position. In this position, a lug 135 provided in said hood portion 130 will cooperate with the upper portion 11 of the capsule 10 which has remained in the loading opening 121. Thus, and as clearly illustrated in Figures 5 and 6, when of the total closure of the cover 130, the pin 135 will cause the expulsion of the upper portion 11 of the capsule from the loading opening 121 to the inside of the dispersion chamber 111. In this position of Figure 6 , where the device is again completely closed, the capsule 10 has been broken in two, the two upper 11 and lower 12 parts of the capsule 10 resting in the dispersion chamber 111 on the bottom (formed by the hatch 150) and with the powder at least partially expelled from said capsule portions. The device is then ready for inhalation. Figure 7 illustrates the inhalation phase. To inhale, the user places his mouth around the dispensing orifice 131 of the hood 130 and sucks in the direction of the arrow B, shown in FIG. 7. In doing so, he creates a stream of air at the same time. inside the dispersion chamber 111 which will swirl the two parts of the capsules 11 and 12 inside said dispersion chamber 111. This swirling illustrated by the arrow C in Figure 7 will allow a total emptying of said parts of capsules but also a good dispersion of the powder, and in particular a deagglomeration of any heaps of powder that could have formed. Optionally, additional air inlets may be provided in the dispersion chamber to promote swirling of the inhalation stream. The swirling powder will then be expelled from the dispersion chamber 111 by the inhalation flow through a second opening 142 provided in the slide member 140 and which, in this inhalation position, is facing the a part to the dispersion chamber 111 and secondly to the loading opening 121. As can be seen more clearly in FIG. 11, the cover 130 advantageously comprises a grid 137 through which the powder will be able to pass and be expelled in In particular, the grid prevents the capsule parts 11, 12 from being expelled from the dispersion chamber. The user then inhales the dose of powder that was initially contained in the capsule 10. Advantageously, said dispersion chamber may have a frustoconical shape narrowing towards the dispensing orifice 131, in particular to accelerate the inhalation flow by direction of said orifice.

After inhalation, the user opens the cover 130 again, which, as before, will tilt the hatch 150 at the end of opening. This tilting of the hatch 150 illustrated in FIG. 8 will make it possible to evacuate the two empty capsule parts 11 and 12 from the dispersion chamber 111. In this position of FIG. 8, the device is thus ready for a next io. use. Of course, if this next use is not immediate, the user can close the device and wait to reopen it the next time he needs it. Alternatively, the user is not obliged to empty empty capsule parts after each inhalation but it can of course only do when the next opening of the device 15 when it wants to load a new capsule. Advantageously, as illustrated in particular in Figure 1, the hatch 150 may include one or more pins (s) 156 which snaps (s) slightly into the bottom of the body 110 in the closed position, to ensure a safe closure and reliable hatch 150 in closed position. Figures 11 and 12 show openings 116 formed in the bottom of the body 110 through which said latching lugs 156 of the door will be able to pass. Of course, this snap is not too strong not to hinder the opening of the hatch when the user opens the hood 130.

Figs. 9 and 10 show perspective views of the device in closed and open positions, and Figs. 11 and 12 are views similar to Figs. 9 and 10 but partially cut away, showing the internal structure of the device in these two positions. The device of the invention is therefore particularly simple and clever. It consists of a small number of parts, so it is inexpensive to manufacture and assemble. On the other hand, the presence of a dispersing chamber and portions of swirling empty capsules allow the powder to be deagglomerated and thus guarantee a better distribution thereof to the user during inhalation. Finally, the evacuation of empty capsule parts does not require disassembly of the device which limits the risk of pollution thereof. The absence of disassembly of the device also avoids the risks of not being able to reassemble it, or to misplace the disassembled parts, in particular in children or the elderly. In addition, the manipulation of the device, that is to say the opening and closing of the cover 130, does not require manipulating the portion forming the mouthpiece around the dispensing orifice 131. could consider a specific gripping part for handling said hood. The risk of contamination at the dispensing orifice 131 is therefore also limited. The method of use of the device is very simple, the user having to move the cover between its two end positions to fully operate the device. Thus, he opens the hood first, then he inserts a capsule, he closes the hood and inhales. Various modifications are also possible for a person skilled in the art without departing from the scope of the present invention as defined by the appended claims. In particular, the various features and functionality of the device described with reference to the drawings may be combined with each other in any suitable manner.

Claims (1)

1. dry powder inhaler (100), comprising a body (110) containing a dispersion chamber (111), a cover (130) pivotally mounted on said body between a closed position and an open position, said cover having an orifice; dispenser (131) through which the user inhales, the inhaler further comprising a loading opening (121) receiving a capsule (10) containing a dose of dry powder to be inhaled, characterized in that the inhaler comprises a sliding member (140) meshing with said cover (130), moving said cover from its open position to its closed position moving said laterally translatable sliding member to open the capsule disposed in said loading opening (121). 2. Inhaler according to claim 1, wherein said capsule (10) comprises an upper part (11) and a lower part (12) separable from said upper part, said sliding member (140) cooperating with said lower part (12). ) to separate it from said upper part (11) when said cover (130) returns to its closed position. 20 3. Inhaler according to claim 1 or 2, wherein said sliding member (140) comprises at least one toothing (145, 146) cooperating with at least one toothed element (161, 162) integral in rotation with said cover (130). 25 4. Inhaler according to any one of the preceding claims, wherein said sliding member (140) is disposed below said loading opening (121) in the right position of the inhaler, said sliding member (140) having a first opening (141) disposed opposite said loading opening (121) 30 when the hood (130) is in the open position, and a second opening (142) disposed facing said loading opening (121) when the hood (130) is in closed position. 5. Inhaler according to claim 4, wherein said lower part (12) of the capsule passes through said first opening (141) of said sliding member (140) when the capsule (10) is inserted into said loading opening (121). An inhaler according to any one of the preceding claims, wherein a plate portion (120) is attached to said body, said plate portion (120) having said loading aperture (121) and guide means ( 129) for guiding the translational movement of said slide member (140). 15 7. Inhaler according to claim 6, wherein said guide means comprise rails (129) cooperating with projections (149) of said sliding member (140).